15.1Tenets of General Relativity 15.2Tests of General Relativity 15.3Gravitational Waves 15.4Black Holes General Relativity CHAPTER 15 General Relativity.

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Presentation on theme: "15.1Tenets of General Relativity 15.2Tests of General Relativity 15.3Gravitational Waves 15.4Black Holes General Relativity CHAPTER 15 General Relativity."— Presentation transcript:

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15.1Tenets of General Relativity 15.2Tests of General Relativity 15.3Gravitational Waves 15.4Black Holes General Relativity CHAPTER 15 General Relativity Time and space and gravitation have no separate existence from matter. Albert Einstein

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15.1: Tenets of General Relativity General relativity is the extension of special relativity. It includes the effects of accelerating objects and their mass on spacetime. As a result, the theory is an explanation of gravity. It is based on two concepts: (1) the principle of equivalence, which is an extension of Einstein’s first postulate of special relativity and (2) the curvature of spacetime due to gravity.

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15.2: Tests of General Relativity Bending of Light During a solar eclipse of the sun by the moon, most of the sun’s light is blocked on Earth, which afforded the opportunity to view starlight passing close to the sun in The starlight was bent as it passed near the sun which caused the star to appear displaced. Einstein’s general theory predicted a deflection of 1.75 seconds of arc, and the two measurements found 1.98 ± 0.16 and 1.61 ± 0.40 seconds. Since the eclipse of 1919, many experiments, using both starlight and radio waves from quasars, have confirmed Einstein’s predictions about the bending of light with increasingly good accuracy.

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Gravitational Lensing When light from a distant object like a quasar passes by a nearby galaxy on its way to us on Earth, the light can be bent multiple times as it passes in different directions around the galaxy.

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Light Retardation As light passes by a massive object, the path taken by the light is longer because of the spacetime curvature. The longer path causes a time delay for a light pulse traveling close to the sun. This effect was measured by sending a radar wave to Venus, where it was reflected back to Earth. The position of Venus had to be in the “superior conjunction” position on the other side of the sun from the Earth. The signal passed near the sun and experienced a time delay of about 200 microseconds. This was in excellent agreement with the general theory.

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15.4: Black Holes While a star is burning, the heat produced by the thermonuclear reactions pushes out the star’s matter and balances the force of gravity. When the star’s fuel is depleted, no heat is left to counteract the force of gravity, which becomes dominant. The star’s mass collapses into an incredibly dense ball that could warp spacetime enough to not allow light to escape. The point at the center is called a singularity. A collapsing star greater than 3 solar masses will distort spacetime in this way to create a black hole. Karl Schwarzschild determined the radius of a black hole now known as the Schwarzschild radius.

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15.3: Gravitational Waves When a charge accelerates, the electric field surrounding the charge redistributes itself. This change in the electric field produces an electromagnetic wave, which is easily detected. In much the same way, an accelerated mass should also produce gravitational waves. Gravitational waves carry energy and momentum, travel at the speed of light, and are characterized by frequency and wavelength. As gravitational waves pass through spacetime, they cause small ripples. The stretching and shrinking is on the order of 1 part in even due to a strong gravitational wave source. Due to their small magnitude, gravitational waves would be difficult to detect. Large astronomical events could create measurable spacetime waves such as the collapse of a neutron star, a black hole or the Big Bang. This effect has been likened to noticing a single grain of sand added to all the beaches of Long Island, New York.

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Gravitational Wave Experiments Taylor and Hulse discovered a binary system of two neutron stars that lose energy due to gravitational waves that agrees with the predictions of general relativity. LIGO is a large Michelson interferometer device that uses four test masses on two arms of the interferometer. The device is meant to detect changes in length of the arms due to a passing wave. NASA and the European Space Agency (ESA) were jointly developing a space-based probe called the Laser Interferometer Space Antenna (LISA) which was to measure fluctuations in its triangular shape.